Laminate assembly sealing method and arrangement

ABSTRACT

An example laminate assembly pressurization arrangement includes a plurality of laminations arranged in a laminate stack. The plurality of laminations are movable between sealed positions and unsealed positions relative to each other. An end plate is adjacent the laminate stack. A housing is configured to establish a first volume together with the end plate. A first group of tie rods is directly secured to the end plate and is configured to move the end plate to a first position that holds the plurality of laminations in sealed positions. A second group of tie rods is directly secured to the housing. Pressurizing the first volume limits movement of the end plate away from the first position.

This application is a divisional of U.S. patent application Ser. No. 12/546,765 filed Aug. 25, 2009.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was made with government support under Contract No. N00173-01-D-2007 awarded by the Defense Advanced Research Projects Agency, which is an agency of the United States Department of Defense. The United States Government, therefore, may have certain rights in this invention.

BACKGROUND

Laminate assemblies having stacks of laminations are used in a variety of applications, such as fuel cell and electrolyzer applications. Sealing the interfaces between laminations of the laminate assembly desirably prevents overboard leakage of operating fluids from the laminate assembly and cross-cavity leakage of operating fluids from internal cavities established within the laminate assembly. Laminate assemblies utilize various seals to limit overboard and cross-cavity leakage. Example seals include elastomeric coating seals, gasket seals, or relying on the elastic nature of membrane laminations. Notably, these seals rely on an applied load pressurizing the seal to prevent leakage.

Many systems having laminate assemblies apply a preload to the laminate assembly using tie rods. Tightening the tie rods forces the laminations of the laminate assembly and associated seals into a sealed relationship with each other. The maximum amount of preload is limited by the compression capacity of the laminations. After the preload is applied, the internal cavities within the laminate assembly are pressurized. As known, the pressurizing can relax or otherwise disrupt the sealed relationship because the internal pressure forces the laminations against the direction of the preload. Disrupting the sealed relationship can undesirably result in leaks.

SUMMARY

An example laminate assembly pressurization arrangement includes a plurality of laminations arranged in a laminate stack. The plurality of laminations are movable between sealed positions and unsealed positions relative to each other. An end plate is adjacent the laminate stack. A housing is configured to establish a first volume together with the end plate. A first group of tie rods is directly secured to the end plate and is configured to move the end plate to a first position that holds the plurality of laminations in sealed positions. A second group of tie rods is directly secured to the housing. Pressurizing the first volume limits movement of the end plate away from the first position.

Another example laminate assembly pressurization arrangement includes a laminate assembly establishing a first enclosed volume. The laminate assembly has a plurality of laminations. An end plate is adjacent the laminate assembly. The end plate establishes a portion of a second volume. The end plate is configured to urge the laminations toward sealed positions relative to each other when the second enclosed volume is pressurized.

These and other features of the example disclosure can be best understood from the following specification and drawings, the following of which is a brief description:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a longitudinal cross-section through an example electrolyzer having a laminate assembly.

FIG. 2 shows a bottom view of the FIG. 1 electrolyzer.

FIG. 3 shows a perspective view of an example end plate from the FIG. 1 electrolyzer.

FIG. 4 shows a perspective view of another example electrolyzer having a laminate assembly.

DETAILED DESCRIPTION

Referring to FIGS. 1 and 2, an example electrolyzer 10 includes a laminate assembly 14 held between a first end plate 18 and a second end plate 22. A fuel cell includes the laminate assembly 14 in another example. One face of the first end plate 18 contacts the laminate assembly 14. An opposing face of the first end plate 18 establishes the first enclosed volume 30 together with the first housing 26. The first enclosed volume 30 is adjacent a first end portion 32 of the laminate assembly 14. One face of the second end plate 22 contacts the laminate assembly 14. An opposing face of the second end plate 22 establishes the second enclosed volume 38 together with the second housing 34. The second enclosed volume 38 is adjacent a second end portion 40 of the laminate assembly 14.

The laminate assembly 14 includes a plurality of laminations 42. The laminations 42 establish internal cavities within the laminate assembly 14 as is known. The laminations 42 are movable between sealed positions and unsealed positions relative to each other. In this example, the sealed positions permit less leakage of fluid from the laminate assembly 14 than the unsealed positions. The sealed positions also permit less leakage of fluid between the internal cavities of the laminate assembly 14 than the unsealed positions. The pressure within the internal cavities of the laminate assembly 14 is represented by P_(i) in this example.

A first group of tie rods 46 secure the first end plate 18 relative to the second end plate 22. The example first group of tie rods 46 is secured to the housing 34. In this example, the tie rods within the first group of tie rods 46 include threaded portions 50 that are configured to engage nuts to secure the first end plate 18 relative to the second end plate 22. Tightening the nuts onto the threaded portions 50 of the first group of tie rods 46 urges the first end plate 18 toward the second end plate 22, which compresses the laminate assembly 14 and moves the laminations 42 to sealed positions relative to each other. The example first end plate 18 moves relative to the second end plate 22 as the first group of tie rods 46 is tightened. In this example, the laminate assembly 14 is preloaded by tightening the first group of tie rods 46. Although the first group of tie rods 46 and the second group of tie rods 54 are shown as tie rods in this example, other examples include using bolts, clamps, etc., in place of, or in addition to, the tie rods.

A second group of tie rods 54 engage the first housing 26 and the second housing 34. Notably, the first group of tie rods 46 is separate from the second group of tie rods 54. That is, the first group of tie rods 46 includes different tie rods and is configured to connect to different components than the second group of tie rods 54.

In this example, the tie rods within the second group of tie rods 54 include threaded portions 58 that are configured to engage nuts to secure the first housing 26 relative to the second housing 34. Tightening the nuts onto the threaded portions 58 urges the first housing 26 toward the second housing 34. The second group of tie rods 54 is lightly preloaded to load all the tie rods within the second group of tie rods 54 in this example.

The example laminate assembly 14 has a generally circular cross-section and establishes multiple apertures 62 radially positioned near the outer radial edge of the laminate assembly. Each of the apertures 62 are configured to receive one of the tie rods from the first group of tie rods 46 or the second group of tie rods 54.

The first end plate 18 and the second end plate 22 include apertures 66 configured to receive a tie rod from the second group of tie rods 54. The apertures 66 are sized such that the tie rod from the second group of tie rods 54 is free to move relative to the end plates 18 and 22 as the tie rods in the first group of tie rods 46 are tightened to the first end plate 18, the second end plate 22, or both.

The example first housing 26 includes a channel 70, or hole, that permits movement of the first group of tie rods 46 as the first group of tie rods 46 is tightened or moves relative to the first housing 26.

Dynamic seals 74 are positioned between the first end plate 18 and the first housing 26 to facilitate holding fluid within the first enclosed volume 30. A static seal 78 is positioned between the second end plate 22 and the second housing 34 to facilitate holding fluid within the second enclosed volume 38. Spring energized dynamic seals 74 and static seals 78 are shown. Other example seals include a bellows, a diaphragm, or a reinforced O-ring seal.

As can be appreciated from the figures, the example first housing 26 and the example second housing 34 are dome shaped. The first enclosed volume 30 and the second enclosed volume 38 have a generally hemispherical shape. Notably, the enclosed volumes 30 and 38 are disposed at the ends of the laminate assembly 14 and do not encircle the laminate assembly 14. In the disclosed examples, two domes are used. In another example, only one dome (or only the first housing 26) is used.

In this example, the pressure of the first enclosed volume 30 and the second enclosed volume 38 is represented by P_(e). After the laminate assembly 14 is preloaded by tightening the first group of tie rods 46, P_(e) is increased to oppose movement of the first end plate 18 away from the laminate assembly 14. The pressure P_(e) effectively neutralizes the pressure P_(i) such that the first group of tie rods 46 does not respond to the pressure P_(i). The second group of tie rods 54 instead carries the pressure load associate with pressurizing the laminate assembly 14. The first group of tie rods 46 is thus sized to accommodate the preload, and the second group of tie rods 54 is sized to accommodate the pressures P_(i) and P_(e).

Fluid is introduced to the laminate assembly 14 through a plurality of fluid feed ports 82. The fluid feed ports 82 are axially extending in this example. In another example the fluid feed ports 82 are radially extending.

In one example the fluid is water, which the electrolyzer 10 breaks down into hydrogen and oxygen. The example electrolyzer 10 includes a controller 86 configured to control fluid flow from a fluid supply 90 to the laminate assembly 14. The controller 86 controls P_(i) by controlling the fluid supply 90. Introducing fluid to the laminate assembly 14 pressurizes the internal cavities of the laminate assembly 14 and increases P_(i). In this example, P_(e) limits movement of the laminations 42 toward unsealed positions. Limiting this movement maintains the sealed relationship of the laminations 42 within the laminate assembly 14. In the prior art, increasing P_(i) moved the laminations 42 toward unsealed positions.

A controller 94 is configured to control fluid flow from a fluid supply 98 to the first enclosed volume 30 and the second enclosed volume 38. The example fluid is nitrogen, and the controller 86 controls P_(e) by controlling the flow of nitrogen to the first enclosed volume 30. A person having skill in this art and having the benefit of this disclosure would understand how to pressurize the first enclosed volume 30 and the second enclosed volume 38 using the fluid supply 98 and the controller 94 by incorporating a suitable valve arrangement into the electrolyzer 10, for example.

In one example, the first enclosed volume 30, the enclosed volume 38, and the internal cavities within the laminate assembly 14 are fluidly coupled. That is, increasing the pressure P_(i) directly increases the pressure P_(e). Such an example includes pressurizing the laminate assembly 14, the first enclosed volume 30 and the second enclosed volume 38 with the same fluid. Such an example may not require the fluid supply 98. Other examples include using the hydrogen from the electrolyzer process to increase the pressure P_(e). Typically one of the fluids in the laminate assembly 14 is used to pressurize the enclosed volume 30 and the enclosed volume 38

Referring to FIG. 3, the first end plate 18 includes a plurality of apertures 99 that extend longitudinally nearly through the first end plate 18. Incorporating the plurality of apertures 99 reduces the overall weight of the first end plate 18 while maintaining the strength of the first end plate 18. The first end plate 18 comprises a material stiff enough to facilitate uniform compression of the laminate assembly 14.

Referring to FIG. 4, another example electrolyzer 100 includes a plurality of cells, each having laminate assemblies 14 a. A plurality of nuts 102 secure the threaded portions 58 for the second group of tie rods 54.

Features of the disclosed examples include maintaining a sealing relationship between adjacent laminations with reduced structure and complexity. Another feature of the disclosed example is the use of two independent groupings of tie rods. One group is for preloading the laminate assembly, and the other group is for responding to pressurization of the laminate assembly. Yet another feature is the use of a dynamic seal between the dome and the first end plate. The dynamic seal facilitates the transmission of pressure load through the first end plate to the laminate assembly. Yet another feature of the disclosed example is a relatively lightweight and low volume active compression system that is independent from the preload system. For example, the first end plate and the second end plate can be lightweight because the only substantial force acting on them is the preload force.

Although a preferred embodiment has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention. 

We claim:
 1. A laminate assembly pressurization arrangement comprising: a plurality of laminations arranged in a laminate stack, the plurality of laminations moveable between sealed positions and unsealed positions relative to each other; an endplate adjacent the laminate stack; a housing configured to establish a first volume together with the endplate; a first group of tie rods secured relative to the endplate and configured to move the endplate to a first position that holds the plurality of laminations in sealed positions; and a second group of tie rods secured relative to the housing, wherein pressurizing the first volume limits movement of the endplate away from the first position.
 2. The assembly of claim 1 wherein the first group of tie rods is configured to be moveable relative to the housing.
 3. The assembly of claim 1 wherein the housing comprises a dome.
 4. The assembly of claim 3 comprising a dynamic seal disposed between the dome and the endplate.
 5. The assembly of claim 1 wherein the first group of tie rods extend through a first group of apertures established in the plurality of laminations and the second group of tie rods extend through a second group of apertures established in the plurality of laminations.
 6. The assembly of claim 5 wherein the laminations have a circular cross-sectional profile, the first group of apertures and the second group of apertures positioned near a radially outer edge of the laminations.
 7. The assembly of claim 1 including a controller configured to control fluid flow to the first volume to control pressure within the first volume.
 8. The assembly of claim 1 including a channel in the housing for permitting movement of the first group of tie rods relative to the housing.
 9. The assembly of claim 1 wherein the surface area of the first volume side of the endplate is the same or greater than the surface area of a laminate side of the endplate.
 10. The assembly of claim 1 wherein the laminate stack is configured to be pressurized with a first fluid and the first volume is configured to be pressurized with a different second fluid.
 11. The assembly of claim 1 wherein the first group of tie rods extends a first length and the second group of tie rod extends a second length, the second length greater than the first length.
 12. A laminate assembly pressurization arrangement comprising: a laminate assembly establishing a first enclosed volume, the laminate assembly including a plurality of laminations; and an endplate adjacent the laminations, the endplate establishing a portion of a second enclosed volume, wherein the endplate is configured to urge the laminations toward sealed positions relative to each other when the second enclosed volume is pressurized.
 13. The assembly of claim 12 including a first tie rod arrangement configured to hold the second enclosed volume relative to the laminate assembly.
 14. The assembly of claim 13 including a second tie rod arrangement configured to hold the first enclosed volume relative to the laminate assembly, wherein the first tie rod arrangement only holds the first enclosed volume relative to the laminate assembly.
 15. The assembly of claim 12 including a housing configured to establish the second enclosed volume together with the endplate, wherein the housing is secured relative to the laminate assembly separately from the endplate.
 16. The assembly of claim 12 wherein the first enclosed volume is in fluid communication with the second enclosed volume such that pressurizing one of the first enclosed volume and the second enclosed volume also pressurizes the other of the first enclosed volume and the second enclosed volume. 